This is a recap and summary of sorts of what has turned out to be one of the most fun and interesting wind turbines I've ever built. Here's some photos of the machine from all sides, fully assembled and tested, and ready to go on the tower:
Some of the basic specs:
- The machine is 14' 5" long from the front of the input shaft to the tip of the tail feather.
- Actual rotor size is 148" diameter, or 12.3 feet
- I hooked a rotary spring scale on the cherry picker and lifted the machine off the yaw shaft. It ended up just a big heavier than I expected - 237 lbs
- The machine is pretty well balanced on the yaw shaft, but slightly nose heavy to the tune of about 5 lbs required on the tip of the tail to balance it. This is good, as in normal operation the rotor thrust will almost perfectly balance it on the shaft, meaning less wear to the shaft bushings and needle thrust bearing on the bottom of the yaw tube.
- The generator design was decided on after about a week of testing various configurations to see what would work with a gear driven unit. That was all well discussed earlier in this thread. The generator was tested to 136 amps (this is a 12 volt machine) and is rated at 80 amps continuous, or about 1,200 watts. It's wound with 30 turns of 12 AWG, 12 pole 9 coil configuration with 10" diameter generator rotors, and runs at 2.14x rotor speed.
The blades are from DaveB and DaveM at Royal Wind & Solar in Jamestown, NY. They are Gottingen 222 Hi-Torque airfoils and the blades have no twist or taper. Those guys are superb - I ordered the blades about a week after I started working on the machine and they had them carved, shipped and to my door before I was ready for them. I wanted the lightest blades possible for this machine so they're made of poplar. They use a sealer on them that raises the grain of the wood a bit, so after sanding them out smooth and priming, I painted them with three coats of DuPont Imron with Delthane hardener in GM Olympic White. This is a photo of the blades after they dried and before I mounted them to the hub:
And finally, a high output 12 volt turbine needs a high capacity rectifier, so I built this unit using a 195 amp rectifier stolen out of a Leece-Neville/Prestolite truck alternator:
This turbine will have two 8/3 generator cables down the tower to the base junction, and 1/0 copper buried underground from the base junction into the service panel in the house. You can't stator brake a high-output 12 volt turbine thru the line because they'll just keep right on running fully shorted. So the stator brake switch is located at the base of the tower and is a 100 amp rated GE three-pole safety switch with the fuses removed and replaced with lengths of copper tubing. This machine is outfitted with a tail crank - the cable guide is installed in the yaw tube alongside the generator cables and attaches to the spring bracket at the rear top of the generator. The cable attaches to a stud on the tail boom and goes down thru the center of the tower to a small winch used to crank the tail into the furled position.
So that's about it. Pretty fun machine to build. Hopefully we'll get a nice day soon when I can work outside and get it on the tower.
--
Chris
